Scientists from Rochester Institute of Technology (RIT) and University of Rochester (UR) won $592,000 from the NASA Planetary Instrument Definition and Development Program to design, build and test a detector that should be resilient against radiation damage. The lightweight device will be smaller and consume less power than technology currently in use. The novel readout circuitry design will give the device a radiation tolerance not possible in standard optical detectors.

“All these benefits will lead to lower mission costs and greater scientific productivity,” said Donald Figer, director of the Rochester Imaging Detector Laboratory at RIT and lead scientist on the project, in an RIT press release. “But ultimately, radiation immunity is the focus.”

The new detector is based on a technology created by Ignjatovic and his colleagues at UR in which each pixel reads and converts its signal from analog to digital immediately upon capture. Standard optical detectors lack this capability. Instead, signals must travel along a line of sensors to reach a readout circuit. This wastes energy and leaves the signal vulnerable to radiation damage that degrades the circuit over time.

“Radiation-tolerant detectors are a critical need for NASA in the continued exploration of the solar system,” said McGrath, chief scientist in the Science and Mission Systems Office at NASA Marshall Space Flight Center.

Stefi Baum, director of the Chester F. Carlson Center for Imaging Science at RIT, said, “In space astronomy and planetary missions, detectors are frequently the critical pacing item. By developing detectors with greatly reduced noise properties and greatly enhanced tolerance to radiation damage -- the chief lifetime limiter of detectors in space -- the collaboration should dramatically improve the reach in sensitivity and lifetime of the missions to explore and understand the nature of the planets with which we share our solar system.”

Testing the overall system will determine how the sensors hold up in cryogenic environments in which the detector is cooled to very low temperatures, imitating conditions in space. The device will be tested at RIT's Rochester Imaging Detector Laboratory, a new facility to develop detector technologies for next-generation ground-based and space telescopes.

The imaging detector under development will boast a dynamic range and greater short wavelength sensitivity. Figer said the detector could become a key technology for future planetary missions in the most severe radiation environments. The technology could figure heavily in missions under consideration for NASA’s Discovery, Mars Exploration and New Frontiers programs.

It might someday be used to capture hyperspectral imaging from a platform orbiting the outer planets or their satellites. Cameras looking down on Europa could take a picture of every wavelength at every pixel.

“We could use that information to figure out if there are lakes of water on Europa or hydrocarbons on Titan,” Figer said. “We can figure out the composition of a surface without having to land on it, which we might want to do 10 years later. Then we would know where to land.”

The scientific observation of celestial radiation that has reached the vicinity of Earth, and the interpretation of these observations to determine the characteristics of the extraterrestrial bodies and phenomena that have emitted the radiation.

The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...